Transcript
EFFECTS OF CLIMATE ON PHENOLOGICAL SYNCHRONY BETWEEN BUTTERFLIES AND THEIR HOST PLANTS
Diana Posledovich
Effects of climate on phenological synchrony between butterflies and their host plants
Diana Posledovich
© Diana Posledovich, Stockholm University 2015 ISBN 978-91-7649-162-1 Printed in Sweden by Holmbergs, Malmö 2015 Distributor: Department of Zoology, Stockholm University
Contents
List of papers ........................................................................................... 1 Introduction ............................................................................................. 2 Study system ............................................................................................ 5 Background to the studies........................................................................ 7 Diapause dynamics and phenology .......................................................................... 7 Post-winter thermal reaction norms ......................................................................... 8 Synchrony in the beginning of interaction ................................................................ 9 Interaction outcome depending on the degree of synchrony in phenology ............. 10
Results and conclusions ......................................................................... 11 References ............................................................................................. 14 Acknowledgements ............................................................................... 19 Svensk sammanfattning ......................................................................... 21
List of papers I.
Posledovich D, Toftegaard T, Wiklund C, Ehrlén J, Gotthard K. (2015) Latitudinal variation in diapause duration and post-winter development in two pierid butterflies in relation to phenological specialization. Oecologia, 177(1), 181-190.
II.
Posledovich D, Toftegaard T, Navarro‐Cano JA, Wiklund C, Ehrlén J, Gotthard K. (2014) Latitudinal variation in thermal reaction norms of post‐winter pupal development in two butterflies differing in phenological specialization. Biological Journal of the Linnean Society, 113(4), 981-991.
III.
Posledovich D, Toftegaard T, Wiklund C, Ehrlén J, Gotthard K. Weak effect of spring temperatures on phenological synchrony between herbivore emergence and host plant suitability. Manuscript.
IV.
Posledovich D, Toftegaard T, Wiklund C, Ehrlén J, Gotthard K. The developmental race between maturing host plants and their butterfly herbivore – the influence of phenological matching and temperature. Under review, Journal of Animal Ecology
Paper I © Springer Paper II © Wiley/The Linnean Society of London, Biological Journal of the Linnean Society Papers I and II are reprinted with the permission from the publishers Paper II will also be included into doctoral dissertation of Tenna Toftegaard, 2016
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Introduction Phenology and climate change Phenology – seasonal timing of life history events – is an essential and at the same time easily observed trait of periodic biological phenomena. An appropriate phenological timetable ensures that life-cycle activities are welltimed to coincide with environmental conditions most suitable for growth, reproduction or dormancy. Moreover, in order to occur, the majority of species interactions require a temporal overlap of organisms in certain developmental stages. For example, larval emergence needs to coincide with leaf unfolding in trees, while hatching of bird nestlings needs to be timed to larval peak abundance. The degree of the temporal overlap determines the strength of a species interaction (Russell & Louda 2004; van Asch & Visser 2007). Interactions that can occur only within a narrow time window are considered to be more sensitive to temporal mismatches between the partner species. Therefore, such relationships are likely to face more severe fitness consequences from phenological asynchrony, caused by shifts in species spring phenologies under climate change. Changes in species phenologies, associated with climate change, have been well-documented in many systems across the world (Root et al. 2003; Parmesan 2007). These results emphasize the need for a better understanding of the mechanisms of phenology regulation and ecological consequences of phenological mismatches between interacting species for food webs and communities. The observed changes in phenologies are mostly associated with spring advancements of different magnitudes (Menzel et al. 2006; Parmesan 2007), although delays as well as the absence of response are also observed (Cook, Wolkovich & Parmesan 2012). Negative effects of phenological shifts include species’ exposure to unfavourable environmental conditions (e.g. cold spells in early springs) and weakening the strength of species interactions or even their disruptions (e.g. Russell and Louda 2004; Liu et al. 2011; Boggs 2
and Inouye 2012; Høye et al. 2013). A decrease in temporal overlap between the interacting organisms can be a result of phenological shifts in opposite directions between the species or asymmetric changes in a similar direction (Root et al. 2003; Parmesan 2006, 2007; Cook et al. 2012). Although the impacts of phenological asynchrony are potentially of great importance for predicting both the persistence of individual species (demographical declines or outbreaks (e.g. Lange et al. 2006; Høye et al. 2013; Kudo and Ida 2013) and functional aspects of natural communities (trophical cascades and range shifts (Buse et al. 1999; Harrington, Woiwod & Sparks 1999; Both et al. 2009; Thackeray et al. 2010; Walther 2010), ecological consequences of phenological mismatches are to a large extent unexplored. Asymmetric phenological shifts between
insects and plants can weaken
previously existing herbivore – host plant species interactions and lead to a shift in host use (Liu et al. 2011). Moreover, phenological mismatches are predicted to reconfigure community interactions even if the degree of asynchrony in species phenologies is relatively moderate (Fabina, Abbott & Gilman 2010). Therefore, revealing the important factors that determine species’ spring timing and how their impact may vary at different development stages of a species is an important prerequisite in predicting species phenologies and fitness consequences for the interacting organisms. In order to estimate fitness consequences of variation in the degree of synchronicity for each of the interacting species, one needs to investigate what factors are likely to affect spring phenologies of the species, how these factors will affect the degree of phenological overlap, and how a change in the overlap may translate into species fitness. Insects, being small ectothermic organisms, are particular sensitive to environmental temperatures and commonly use them as cues to regulate their life cycle. Spring temperatures, therefore, are the primary cause of yearly variation in spring emergence, as well as phenological shifts due to climate warming. Thermal sensitivity of species to spring temperatures determines their relative developmental rate and thereby the 3
timing and the degree of overlap between insect herbivores and host plants. The fitness of insect herbivores, however, is determined not only by the ability to synchronize with the period of host plant availability, but also to successfully complete development before the plants become unsuitable for feeding (e.g. Feeny, 1970; Stamp & Deane, 1990; Nava-Camberos et al., 2001). Here, relative larval growth and host plant maturation are strongly affected by thermal conditions during development as well (Stamp & Deane 1990; Hill & Hodkinson 1992). Therefore, studies on plant-insect synchrony are not complete without further investigation of the outcome of the interaction in relation to temperature. Another important aspect is that temperate insects typically spend winter in the state of developmental arrest – diapause. Among other important roles, diapause prevents insects from resuming development during warm periods of weather fluctuation before spring. Insects, therefore, need to terminate diapause before post-winter development can take place. As a result, diapause duration and requirements for its termination contribute to spring phenologies of insect herbivores as well and must be considered when predicting phenological events. The four papers of this thesis address all these factors determining spring phenology in herbivorous butterflies. They investigate spring phenologies and phenological synchrony between a herbivore and its host plants in the context of climate change and aim to answer the following key questions: - How may the timing of spring emergence in herbivorous butterflies be affected by diapause dynamics and thermal reaction norms of their post-winter development? (Paper I and II) - Do thermal reaction norms of the herbivore and its host plants differ and could the difference lead to shifts in spring synchronicity between the species and, ultimately, alter host use pattern in the butterfly? (Paper III) - Does the degree of synchronicity between the butterfly emergence and host plant reproduction affect fitness of the two interacting species? And does 4
thermal sensitivity differ between herbivorous larvae and host plants? (Paper IV) - Is there latitudinal variation in traits that determine spring phenologies and do the answers to the questions above differ depending on latitudinal aspect? (Papers I-IV)? Study system Species depending on synchronicity with short periods of resource availability are considered to be more vulnerable to phenological shifts caused by climate change (van Asch & Visser 2007). Such species have a higher risk of mistiming with lower trophic levels if phenological responses are divergent among levels, for instance if phenological changes of insect herbivores and their host plants vary in magnitude (Parmesan 2006; van Asch & Visser 2007). For this reason, generalist species with broader larval diet are expected to experience relatively moderate spring advances due to synchronization with host plants. Even though these species are affected by temperature as well, they have a greater chance that at least some of their host plant species would have spring phenologies similar to them (Dennis and Shreeve 1991; Forrest and Miller-Rushing 2010; but see Diamond et al. 2011). Furthermore, univoltine insects with a fixed overwintering life stage are thought to have a less flexible phenology and therefore suffer the strongest negative impact under climate change (Bale & Hayward 2010). We used Anthocharis cardamines (the orange tip butterfly) and five of its most commonly used Brassicaceae host plant species as a model system for the following reasons. First, adult A. cardamines butterflies emerge from pupae in spring and the butterfly larvae feed on the growing reproductive organs of the host plant species. Therefore, both the flight time of adult butterflies and development of larvae depend on a short period of resource availability, implying that the interaction refers to the most vulnerable “timelimited” type. Second, Anthocharis cardamines is among the butterfly species 5
that have most strongly advanced their spring emergence for the last 20-30 years (Diamond et al. 2011; Karlsson 2014; Navarro-Cano et al. 2015) and therefore, its spring phenology is likely to be particular sensitive to climate warming. Third, Anthocharis cardamines is an obligatory univoltine species, which are considered to have a less flexible phenology and suffer the most pronounced negative impacts from changing climate (Post & Forchhammer 2008; Bale & Hayward 2010). Finally, annual and perennial plants species reveal different magnitude of shifts in spring phenologies (Fitter & Fitter 2002); and host plants of A. cardamines include both annual and perennial species.
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Anthocharis cardamines: a) egg b) 1st instar larva c) 5th instar larva d) female e) male Photos by Vlad Dinca
A part of the studies involved another pierid butterfly – Pieris napi (the green-veined white). Larvae of this butterfly feed on green leaves of various Brassicaceae plants and, therefore, are not limited by a short period of plant reproduction, and in the study area have two generations during the growing season. Thus, the two butterfly species are oligophagous and to a large extend share plant species range. However, A. cardamines can be referred to as phenological specialist, depending on a particular developmental stage of the host plants. In contrast, P. napi can be regarded as phenological generalist, 6
utilizing plants at any developmental stage as long as they have green leaves. These features make the two species interesting to compare for possible adaptations in life-history traits, associated with the different feeding strategies.
Background to the studies Diapause dynamics and phenology In order to emerge in spring at the right time to meet favourable environmental conditions or to match with a certain host plant stage, insect herbivores need to resume development after the winter period of developmental arrest. Usually post-winter development begins in response to the onset of permissive environmental conditions after diapause is terminated (Koštál 2006). Exposure to favourable conditions before this point does not lead to termination of diapause and resumption of development, as many species are not sensitive to environmental cues during the period of endogenous developmental arrest (Tauber & Tauber 1976; Koštál 2006). Therefore, diapause duration and factors influencing it affect life cycle timing of insects in spring Insects with shorter diapause that are not limited by resource availability are likely to strongly advance their spring activities and demonstrate rapid phenological shifts in response to warmer winters and earlier springs, associated with climate change (Forrest & Miller-Rushing 2010). Conversely, species with long diapause and species with the so-called chilling requirements (i. e. a certain number of “chilling degree-days” below the developmental threshold (Hodek 1996, 2002) are expected to have developmental delays rather than advancements in spring after warmer and/or shorter winters, since the post-winter development can resume only after the chilling thresholds are met (Bale & Hayward 2010; Cook et al. 2012; Williams, Henry & Sinclair 2015). Concerning the two butterfly species, used in our study, only P. napi is known to vary the timing of adult emergence
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depending on duration of cold winter conditions (Forsberg & Wiklund 1988). Whether this variation was due to requirement of a certain diapause length, independent of temperatures, or due to accumulation of cold days, is not clear. As for the other butterfly species – A. cardamines – such studies have not been previously done for it. In paper I we investigate latitudinal variation in diapause duration and existence of chilling requirements that influence post-diapause development in two butterfly species A. cardamines and P. napi.
Post-winter thermal reaction norms Phenological responses of ectothermic organisms are strongly influenced by ambient temperatures (Parmesan, 2006). Therefore climate change, associated with increase in average temperatures, has entailed shifts in phenologies of many species. All phenotypic trait values (e.g. growth rate, which in its turn determines timing of life-cycle events) that can be expressed by a given genotype under a range of environmental temperatures can be described by thermal reaction norms (Huey & Kingsolver 1989). Many ectotherms, and particularly insects, have evolved genetically based growth capacities increasing with latitude, which are thought to be an adaptation to strong gradients in seasonality (Conover & Schultz 1995). This type of latitudinal pattern is called countergradient variation in growth, and is engendered by the need to maximize reproductive success and survival under decreasing length of the growing season at higher latitudes (Conover & Schultz 1995). The opposite pattern –cogradient variation (Conover & Schultz 1995) – is mainly found in morphological traits, like body shape or body size (Conover, Duffy & Hice 2009). So far, cogradient patterns in growth rate have been described only in relation to the so-called “saw-tooth” phenomenon, when the rate of development sharply decreases at certain latitude due to relaxed time limitation in a population, passing to a lower number of 8
generations (Roff 1980; Nygren, Bergström & Nylin 2008; Välimäki et al. 2013). In this situation when there is just not enough time to produce two generations individuals have relatively more time for development when producing only a single generation. Therefore, selection favors slower development, as maintaining high growth rates can be associated with tradeoffs with other life history traits and with predation risk (Roff 1980; Gotthard 2000). However, high rate of gene flow between populations may counteract any local genetic differentiation. If so, any observed differences in growth rate between populations are caused only by manifestation of one common reaction norm in response to variation in local thermal conditions. Thus, differences in the field can be due to different genotypes or to phenotypic plasticity, and disentangling the basis of population variability is a key step in understanding the nature of variation in phenological responses to the same environmental change (Phillimore et al. 2012). In paper II latitudinal variation in thermal reaction norms of pupal growth rate in two butterfly species A. cardamines and P. napi was explored in order to test if the timing of butterfly emergence in the field is determined by genetic differentiation (local adaptations) or reaction norms (phenotypic plasticity). Here, pupal developmental rate in the post-winter period is an important trait that regulates the timing of the butterflies’ emergence, which in its turn determines the degree of temporal overlap with the host plants.
Synchrony in the beginning of interaction Reproductive success and survival of many herbivorous insects in any given season depend on the degree of phenological synchrony (i.e. simultaneous emergence or development (van Asch & Visser, 2007) with the host plants. If ovipositing female butterflies emerge too early, they can live for some period “waiting” for the host plants to become available during their lifetime, which may last several weeks. However, the longer the “waiting” 9
period, the higher risk of mortality before the beginning of egg-laying. If butterflies emerge too late, they may not have time to realize their fecundity or may be outcompeted by other females for the available/suitable host plants since each female oviposits a single egg per plant individual (Wiklund & Åhrberg 1978; Dempster 1992). Therefore, a shorter period between butterfly emergence and plant availability is likely to increase female reproductive success. Since dormant herbivores cannot use the actual abundance of plants as a cue for starting their own development, they need to predict the timing of the relevant phenological events in host plants and develop accordingly in order to emerge at the right time (Visser et al. 2010). In this case natural selection would favor developmental plasticity in relation to cues that effect phenology of the host plants, and temperature is one of the most important and universal seasonal cues for different groups of organisms (Dennis & Shreeve, 1991). Direction and the relative magnitude of change in phenologies between the herbivores and host plants in response to new thermal environments, caused by spring warming, determine whether the phenological overlap between them will persist. In paper III we explored how phenological synchrony between the emergence of A. cardamines and reproductive stages of its host plants was affected by their relative thermal sensitivity under a range of spring conditions.
Interaction outcome depending on the degree of synchrony in phenology Finally, does the degree of phenological synchrony between a plant and a herbivore affect their respective fitness? Several studies have demonstrated negative effects of herbivores emerging too early (due to starvation) and too late (due to accumulation of defensive compounds by host plants) (e.g. Feeny 1970; Stamp and Deane 1990). The consequences of a herbivore’s timing for the host plants (represented mainly by tree species) were not estimated within 10
the framework of those studies. While accumulation of secondary metabolites can also take place in herbaceous host species (e.g. Brown et al. 2003), they pose an additional challenge for less mobile herbivores because of their typically smaller size and rapid development (especially in annuals) in response to increasing temperatures (Atkinson & Porter 1996). As both plant and larval development after the beginning of the interaction (i.e. oviposition) are influenced by thermal environment, depending on the relative thermal sensitivity in their growth rates either a larva of A. cardamines may outgrow the plant and consume all its reproductive organs, or a plant may mature and cast the seeds before the larva completes its development. For example, temperature was shown to affect larval survival in Euphydryas editha bayensis by influencing the rate of senesce in some of its host plant species (Hellmann 2002). In paper IV the combined effect of the degree of phenological overlap in the beginning of the insect-plant interaction and thermal conditions after egglaying was investigated for both A. cardamines’ larvae and different host plant species. Larval performance and risk of being outgrown by the plant were estimated for the butterfly, while the probability of outgrowing a larva and form mature seeds was assessed for each of five host plant species.
Results and conclusions Paper I The two species of the butterflies showed distinct latitudinal patterns both in diapause duration and the existence of chilling requirements. Diapause duration of the phenological generalist P. napi showed a latitudinal increase that is likely to be adaptive as winters are longer at higher latitudes. Longer diapause and lower metabolic rates, associated with it, keep insects from resuming development under short-term temperature fluctuations as well as from depleting energy nutrient storage (Denlinger 2002; Hahn & Denlinger 2007; Williams et al. 2012, 2015). Pieris napi was also found to have chilling 11
requirement, as diapause duration decreased with pupal exposure to lower temperature during winter. In contrast, the phenological specialist A. cardamines exhibited relatively short diapause duration in all sampled populations, independent of latitudinal origin. In addition, no chilling requirement in diapause termination was detected for this species. We interpret these differences in overwintering strategies between the two butterfly species as the result of selection to synchronize spring emergence with favourable abiotic conditions in P. napi, whilst in A. cardamines timing to the particular developmental stages of host plants is under stronger selection. As a consequence, warmer and shorter winters may cause developmental delays in northern populations of P. napi but have no effect on spring phenology of A. cardamines. Paper II Both species of butterflies revealed cogradient latitudinal variation in post-winter developmental time. However, the pattern of variation indicates that these latitudinal clines are due to different reasons in the two species. The cogradient pattern of A. cardamines was likely due to selection for phenological synchronicity with its local host plant community, most species of which also demonstrated cogradient variation in the initiation of reproduction (Toftegaard et al., 2015 in review). The latitudinal pattern in P. napi was primarily an effect of slow development of only a fraction of pupae from the most northern population, which may be due to the presence of both bivoltine and univoltine strategies in this northern location, i.e. due to the “saw-tooth” effect. Paper III Pupal development in three latitudinally different populations of A. cardamines demonstrated temperature-mediated phenological plasticity similar to that of their host plants. This indicates that the butterflies were wellsynchronized with the majority of the plant species across the temperature range, which may be the result of the existing preadaptation caused by highly variable environmental conditions between years. However, since some of the 12
plant species demonstrated higher thermal sensitivity than the butterflies, especially in the northernmost population, we conclude that there is a possibility for host use shifts in A. cardamines under spring warming. Paper IV In general, earlier reproductive stages of host plants at the time of oviposition as well as warmer temperatures were overall beneficial for the butterfly larvae, although the effects also were plant species-specific. This implies that the degree of synchrony of the butterflies’ emergence with early reproductive period in host plants is likely to be important for butterfly fitness, and even moderate mismatches may have negative consequences. On the other hand, the impact was mediated by host plant species identity and therefore the adverse effects from asynchrony are likely to be buffered by a wide range of plant species, utilized by A. cardamines. Host plant fitness was affected neither by the degree of phenological synchrony nor by the subsequent temperature and was dependent only on the species identity. The results of these four studies suggest that the plant-herbivore system of A. cardamines and its host plants, although being temporally constrained, is unlikely to experience detrimental phenological asynchrony under warmer seasonal conditions. In general, the butterflies and host plants demonstrated a quite high degree of synchronicity under a range of spring temperatures both by the beginning of the interaction (oviposition) and in the relative growth rates during it. However, the comparative experiments on pupal and plant development (Paper III) suggest that warmer springs may induce greater variation in plant phenological stages at the time of butterfly emergence in the northernmost population. This may potentially decrease availability of C. pratensis – one of the most reliable and widespread host plant, – as well as A. glabra. Thus, changes in host use patterns may be expected in the northern population in response to warmer spring temperatures. That can be reinforced by larval ability to develop quicker under higher temperatures and with a 13
greater probability complete development before the host plants (Paper IV). Finally, the predicted climate warming during winter would add an extra touch to the picture. Anthocharis cardamines appeared to have short diapause duration and no or very low chilling requirements at all the sampled latitudes. This makes the butterfly ready to resume post-diapause development as soon as the conditions become permissive, advancing its emergence with warmer winters and earlier springs. On the other hand, some if its host plants, like A. thaliana (Simpson & Dean 2002), C. bursa-pastoris (Neuffer & Hurka 1986) and C. pratensis (Thurling 1967), are known to have winter chilling requirements, which may cause delays (Cook et al. 2012) in their spring phenologies in warmer and shorter winters and make these plants available for oviposition at earlier reproductive stages. Thus, despite that temporally constrained species interactions are thought to be particularly sensitive to phenological asynchrony and therefore most vulnerable to climate change, they may still demonstrate a high degree of resilience to factors potentially leading to their disruption. Features that are likely to contribute to persistence of such systems are species diversity of the interactions (i.e. generalist strategy, like larval diet breadth) and a high degree of phenotypic plasticity that is similar between the species as a result of coevolution and adaptation to high environmental variability among years.
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Acknowledgements My most sincere gratitude and appreciation to my main supervisor Karl Gotthard for all the guidance, advice and help, patience and encouragement throughout the years of my doctoral studies. Thank you for always being optimistic and confident about the progress of my work, and never showing any frustration no matter how stubborn I sometimes was. I have never had a chance to stumble. I would also like to wish my deepest thanks to Christer Wiklund, who has predetermined the field of my studies and, in fact, my life during the past six years. Thank you for sharing with me, patiently and in detail (and probably for the millionth time), your immense experience in butterfly biology and handling; demonstrating all kinds of curious creatures that occurred in the lab and telling interesting facts about them (including the larva of the ethereal golden eyes that stroke my imagination). Your feedback on the papers has invariably been the quickest. Rushana, I am indebted to you for introducing me to Christer and making possible my best-choice master project and acquaintance with Zootis. I am also grateful to my second co-supervisor Johan Ehrlén for the valuable comments and advice both in my writing and experimental work. Without the superb supervision the thesis wouldn’t have been successful. All the hard work, both exciting and not very, starting from experiments and fieldwork and all the way up to the writing and publishing we have shared with Tenna Toftegaard. Thank you for the wonderful time we spent together and best memories about my doctoral studies. Elsa Fogelström and Jose A. Navarro-Cano for your participation and great contribution to all that. Huge thanks to Sami Kivelä for always having time and willingness for detailed explanations and help with statistical questions. I have learned a lot from you.
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Inger Haugen for the nice times spent chatting in the office, and Hélène, Alexander, Marianne, Sandra, Yiting, Alyssa, Naomi, Johanna and everyone at Zootis and Museum for the friendly atmosphere and making my days pleasant and fun throughout all these years. Olga, for constantly keeping me updated with the local and world news, and for the master class of the positive attitude to life, дякую. Special thanks to Birgitta Tullberg, the kindest and friendliest person ever. Peter and Philipp for patience when sharing lab skills, instructing and trusting me with the respirometer beast. Vlad Dinca for providing me with all the pictures of the butterflies, including those used in this thesis. Thanks also to administrative personal – Anette, Minna, Ulf, Berit and Siw – for answering all kinds of bureaucratic and technical questions and solving all kinds of problems. Magne Friberg for all your sparkling enthusiasm and support during my master studies (and later on), and for the happy summer of my lab assistantship that put an end to my hungry days. And finally, my parents and sister who always supported me in my crazy ideas of what my life occupation should be, which sometimes required tightening of their belts. Без вас, мои любимые сестра, мама и папа, без вашей любви и неослабевающей поддержки, у меня бы никогда не получилось попасть сюда, выжить и даже стать – страшно сказать – доктором наук. С вами я могу всё. Огромное спасибо дяде Саше и тетё Жанне за чудесную иллюстрацию к моему тезису – самую ответственную её часть, по которой большинство людей будет судить, насколько тезис удался
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Svensk sammanfattning Fenologiska förändringar samt förändringar i graden av fenologisk synkronisering mellan interagerande arter har under den senaste tiden fått mycket uppmärksamhet, särskilt i samband med klimatförändringar. Arter som tidigare var synkroniserade, kan, som en följd av dessa fenologiska förändringar, bli skilda från varandra i tid så interaktionen inte längre är möjlig. Denna typ av förändringar kan påverka enskilda arter, t.ex. genom ökad variation in abundans, men kan även påverka hela ekosystem genom att arter på olika trofiska nivåer inte längre är tidsmässigt matchade, eller genom förändringar i samhällsstruktur. Denna avhandling undersöker effekterna av temperatur och fenologisk synkronisering under våren på interaktionen mellan en herbivor insekt, aurorafjärilen Anthocharis cardamines, och dess värdväxter ur familjen Brassicaceae. Artikel I visar hur vinterns längd och temperaturförhållanden under fjärilens puppdiapaus påverkar kläckningen av adulter på våren samt att dessa egenskaper kan variera mellan arter som skiljer sig åt i födopreferenser. Artikel II visar att de reaktionsnormer som beskriver hur temperaturen under våren påverkar utvecklingshastighet efter övervintring varierar längs latitud, så att populationer längre norrifrån utvecklas långsammare än populationer från mer sydliga områden i hela det undersökta temperaturintervallet. Artikel III visar att temperaturberoende fenologisk plasticitet hos A. cardamines och flertalet av dess viktigaste värdväxter är likartade inom populationer från olika latituder. Detta tyder på att fjärilens tajming till värdväxternas utveckling under våren är väl anpassad för att klara av variation i temperaturförhållanden. Artikel IV undersöker betydelsen av variation i fenologisk synkronisering mellan fjärilen och dess värdväxter samt temperaturförhållanden under våren då larverna tillväxer på sina värdväxter. Här undersöktes effekterna av detta på viktiga komponenter av både fjärilens och växternas fitness. Graden av den fenologisk synkronisering och
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temperaturen efter äggläggningen var båda viktiga faktorer för fjärilens överlevnad och tillväxt. Däremot hade dess faktorer ingen signifikant betydelse för växtens reproduktiva framgång då de attackerades av fjärilslarver. De fyra artiklarna i avhandlingen visar att de utvecklingsmässiga anpassningar som leder till att insektsherbivorer lyckas matcha sin livscykel till variation i värdväxternas fenologi mellan olika år, leder till att interaktionen också är relativt resilient mot förändrade temperaturförhållanden som kan uppstå p.g.a mer storskaliga klimatförändringar. Resultaten visar också att art interaktioner som är begränsade till ett kort tidsfönster under säsongen inte nödvändigtvis är speciellt känsliga för fenologiska förändringar om de involverar arter som är generalister i andra avseenden av interaktionen.
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Doctoral theses from the Department of Zoology 1906. Nils Holmgren: Studien über südamerikanische Termiten. 1907. Lännart Ribbing: Die distale Armmuskulatur der Amphibien, Reptilien und Säugetiere. 1908.
Augusta Ärnbäck-Christie-Linde: Der Bau der Soriciden und ihre Beziehungen zu anderen Säugetieren.
1909.
Adolf Pira: Studien zur Geschichte der Schweinerassen insbesonders derjenigen Schwedens.
1910.
Walter Kaudern: Studien über die männlichen Geschlechtsorgane von Insectivoren und Lemuriden.
1912. Nils Odhner: Morphologische und phylogenetische Untersuchungen über die Nephridien der Lamellibranchier. 1913. Henrik Strindberg: Embryologische Studien an Insecten. 1914. John Runnström: Etudes sur la morphologie et la physiologie cellulaire du développement de l'oursin. 1918.
Olof Hammarsten: Beitrag zur Embryonalentwicklung des Malacobdella grossa.
1920. Bertil Hanström: Zur Kenntnis des centralen Nervensystems der Arachnoiden und Pantopoden. 1921. Axel Palmgren: Embryological and morphological studies on the mid-brain and cerebellum of vertebrates. 1922. Torsten Pehrson: Some points in the cranial development of teleostomian fishes. Gertie Söderberg: Contributions to the fore-brain morphology in Amphibians. 1924. Kåre Bäckström: Contributions to the fore-brain morphology in Selachians. Gert Bonnier: Contributions to the knowledge of intra- and inter-specific relationships in Drosophila. Hialmar Rendahl: Embryologische und morphologische Studien über das Zwischenhirn beim Huhn. 1928. Sven Hörstadius: Über die Determination des Keimes bei Echinodermen. 1932.
Harry Bergqvist: Zur Morphologie des Zwischenhirns bei niederen Wirbeltieren. Gösta Johansson-Kvenne: Beiträge zur Kenntnis der Morphologie und Entwicklung des Gehirns von Limulus polyphemus. Mois Koffmann: Die Mikrofauna des Bodens, ihr Verhältnis zu anderen Mikroorganismen und ihre Rolle bei den mikrobiologischen Vorgänge im Boden.
1936.
Eric Lindahl: Zur Kenntnis der physiologischen Grundlagen der Determination im Seeigelkeim.
1937.
Figge Hammarberg: Zur Kenntnis der ontogenetischen Entwicklung des Schädels von Lepisosteus osseus. Märtha Kindahl: Zur Entwicklung der Exkretionsorgane von Dipnoern und Amphibien.
1942. Egron Vallén: Beiträge zur Kenntnis der Ontogenie und der vergleichenden Anatomie des Schildkrötenpanzers. 1945. Birger Rudebeck: Contribution to fore-brain morphology in Dipnoi. 1948. Gösta Notini: Biologiska undersökningar över grävling. Alf G. Johnels: On the development and morphology of the skeleton of the head of Petromyzon. 1949. Thorolf Lindström: On the cranial nerves of the cyclostomes with special reference to N. trigeminus. Bertil Lekander: The sensory line system and the external bones in the head of some Ostariophysi. 1958. Ragnar Olsson: The subcommisural organ. 1959. Gunnar Bertmar: On the ontogeny of the chondral skull in Characidae, with a discussion on the chondrocranial base and the visceral chondrocranium in fishes. 1961. Armin Lindquist: Über die Morphologie und Biologie von Limnocalanus im Ostseebecken. 1963. Gunnar Fridberg: Morphological studies on the caudal neurosecretory system in teleosts and elasmobranchs. Kjell Engström: Studies on teleostean visual cells. 1964. Valdek Jürisoo: Agro-ecological studies on leafhoppers (Auchenorrhynca, Homoptera) and bugs (Heteroptera) at Ekensgård farm in the province of Hälsingland, Sweden. 1965.
Hubertus Eidmann: Ökologische und physiologische Studien über die Lärchen-miniermot (Coleophora laricella HBN).
1968. Bengt-Owe Jansson: Studies on the ecology of the interstitial fauna of marine sandy beaches. 1970. Göran Malmberg: The excretory systems and the marginal hooks as a basis for the systematics of Gyrodactylus (Monogenoa, Trematoda). Perarvid Skoog: The food of the Swedish badger (Meles meles L.) Yngve Espmark: Mother-young relations and development of behaviour in roe-deer (Capreolus capreolus L.). Bo Ingemar Hjort: Reproductive behaviour in Tetraonidae with special reference to males.
Jan Karl Englund: Population dynamics of the Swedish red fox, Vulpes vulpes (L.). 1971. Björn Ganning: Studies on Baltic rockpool ecosystems. Lars Westin: Studies on the biology and ecology of fourhorn sculpin, Myoxocephalus quadricornis (L.). Hans Ackefors: Studies on the ecology of the zooplankton fauna in the Baltic proper. Lars Wilsson: Observations and experiments on the ethology of the European beaver (Castor fiber L.). A study in the development of phylogenetically adapted behaviour in a highly specialized mammal. 1972. Bo Fernholm: Pituitary and ovary of the Atlantic hagfish. An endocrinological investigation. Anders Bjärvall: Nest-exodus behaviour and nest-site selection of the mallard. Kaj Holmberg: The retina and responses to light in hagfish. 1973. Björn Sohlenius: Growth, reproduction and population dynamics in some bacterial feeding soil nematodes. 1974. Lars-Olof Hagelin: Studies on the development of the membranous labyrinth in lampreys, Lampetra fluviatilis Linné, Lampetra planeri Bloch and Petromyzon marinus Linné. Birgitta Weman: The adenohypophysis of the mink, Mustela vison. AnnMari Jansson: Community structure, modelling and simulation of the Cladophora ecosystem in the Baltic Sea. Arnold Stenmark: Studies on the pea moth (Laspeyresia nigricana Steph) in central Sweden. 1975. Erik Neuman: The dynamics of the coastal fish fauna in the Baltic with special reference to temperature. Tommy Radesäter: Ethological studies on the triumph ceremony of the Canada goose (Branta canadensis L.) - with special reference to ontogeny and causation. Christer Wiklund: Ecological and evolutionary aspects on the host plant biology of Papilio machaon L. Christer Solbreck: Flight habits and environment of a seed bug, Lygaeus equestris (L.) (Heteroptera, Lygaeidae). Finn Sandegren: Social behaviour in the Steller sea lion (Eumetopias jubatus) and northern elephant seal (Miroungas angustirostris). Bo Ekengren: Structural aspects of the Hypothalamo-Hypophysial complex of the roach, Leuciscus rutilus. Inga-Britt Ahlbert: Organization of the cone cells in the retinae of some teleosts in relation to their feeding habits.
1976. Per Haage: Studies on the Baltic Fucus macrofauna. Laila Winbladh: Endocrine pancreas in cyclostomes. Ragnar Elmgren: Baltic benthos communities and the role of the meiofauna. 1977. Eva Norman: Studies on the ecology of the marine woodboring molluscs on the Swedish west coast with special reference to the degradation of wood. Sven Ankar: The soft bottom ecosystem of the northern Baltic proper with special reference to the macrofauna. Olle Lindén: Effects of oils and dispersants on the early development of Baltic herring and some invertebrates from the Baltic Sea. Thorsten Klint: Factors contributing to mate selection in female mallards (Anas platyrhynchos L.) - with particular emphasis on the role of the male nuptial plumage. Otto Kugelberg: Food relations of a seed feeding insect, Lygaeus equestris (L.) (Heteroptera, Lygaeidae). Sverre Sjölander: Reproductive behaviour of the divers (Gaviidae). Peter Öhman: Structure and function of the river lamprey (Lampetra fluviatilis) retina. Mats Olsson: Mercury, DDT and PCB in aquatic test organisms. Baseline and monitoring studies, field studies on biomagnification substances harmful to the Swedish environment. Lars Hernroth: Studies on the population dynamics of zooplankton in the Baltic. 1978. Gunnel Skoog: Aspects on the biology and ecology of Theodoxus fluviatilis (L.) and Lymnea peregra (O. F. Müller) (Gastropoda) in the northern Baltic. Fredrik Wulff: Ecological studies on Baltic rock pools. Greta Ågren: Sociosexual behaviour in the Mongolian gerbil Meriones unguiculatus. Interactions between gonadal hormones and social relationships. 1979. Gunnar Aneer: On the ecology of the Baltic herring with special reference to the Askö-Landsort area. Hans Cederwall: Energy flow and fluctuations of deeper soft bottom macrofauna communities in the Baltic Sea. 1980. Hans Lundberg: Ecology of bumblebees (Hymenoptera Apidae) in a subalpine/alpine area with special reference to food plant and habitat utilization. Stig Sjöberg: Modelling, simulation, and analysis of pelagic ecosystems with special reference to the Baltic Sea. Hans Ahnlund: Aspects of the population dynamics of the badger (Meles meles L.).
Annikki Lappalainen: On the ecology of shallow sandy bottoms in the Baltic Sea with special reference to mud snails (Hydrobiidae). Stellan Hedgren: Ecological aspects of the breeding biology of the guillemot Uria aalge in the Baltic Sea. Bengt Lindlöf: Some aspects of ecology in hares. Jan Landin: Habitats, life histories, migration and dispersal by flight in water beetles (Hydrophilidae and Hydraenidae). Åke Pehrson: Intake and utilization of winter food in the mountain hare (Lepus timidus L.). 1981. Nils Kautsky: On the role of the blue mussel, Mytilus edulis L. , in the Baltic ecosystems. Göran Cederlund: Some aspects of roe deer (Capreolus capreolus L.) winter ecology in Sweden. 1982. Erik Lindström: Population ecology of the red fox (Vulpes vulpes L.) in relation to food supply. Olavi Grönwall: Aspects of the food ecology of the red squirrel (Sqiurus vulgaris L.). Tjelvar Odsjö: Eggshell thickness and levels of DDT, PCB and mercury in eggs of osprey (Pandion haliaetus (L.)) and marsh harrier (Circus aeruginosus (L.)) in relation to their breeding success and population status in Sweden. Göran Nordlander: Systematics and phylogeny of an interrelated group of genera within the family Eucoilidae (Insecta: Hymenoptera, Cynipoidea). Birgitta Sillén-Tullberg: Behavioural ecology and population dynamics of an aposematic seed bug, Lygaeus equestris L. (Heteroptera, Lygaeidae). 1983. Björn Helander: Reproduction of the white-tailed sea eagle Haliaetus albicilla (L ) in Sweden, in relation to food and residue levels of organochlorine and mercury compounds in the eggs. Sven O. Kullander: Taxonomic studies on the percoid freshwater fish family Cichlidae in South America. 1984. Per-Olov Larsson: Some characteristics of the Baltic salmon, Salmo salar L., population. Torbjörn Järvi: On the evolution of inter- and intraspecific communication through natural and sexual selection. Magnus Enquist: Game theory studies on aggressive behaviour. Nils-Ove Hilldén: Behavioural ecology of the labrid fishes (Teleostei: Labridae) at Tjärnö on the Swedish west coast. Helena Obermüller-Wilén: Neuroendocrine studies in the brain of the lancelet, Branchiostoma lanceolatum (Cephalochordata).
Paula Kankaala: On the ecology and productivity of zooplankton in the northern Baltic. Lars-Åke Janzon: Taxonomical and biological studies of Tephritis species (Diptera) and their parasitoids (Hymenoptera). 1986. Kenneth Lindahl: Endocrinological studies on the young salmon, Salmo salar L., with special reference to smoltification. Anders Angerbjörn: Population dynamics of mountain hares (Lepus timidus L.) on islands. Ulf Larsson: The pelagic microheterotrophic food web in the Baltic Sea: Bacteria and their dependence on phytoplankton. Anders Fernö: Aggressive behaviour between territorial cichlid fish and its regulation. Staffan Tamm: Behavioural energetics: Acquisition and use of energy by hummingbirds. 1987. Per-Olof Wickman: Mate searching behaviour of Satyrine butterflies. Erkki Schwanck: Reproductive behaviour of a monogamous cichlid fish Tilapia mariae. Vidar Øresland: Life cycle feeding of the chaetognaths Sagitta setosa and S. elegans in European shelf waters. Odd Lindahl: Plankton community dynamics in relation to water exchange in the Gullmar fjord, Sweden. Sven Jakobsson: Male behaviour in conflicts over mates and territories. 1988. Hans Temrin: Polyterritorial behaviour and polygyny in the wood warbler (Phylloscopus sibilatrix Bechst). Bertil Widbom: The benthic meiofauna of three coastal areas: Structure, seasonal dynamics and response to environmental perturbations. Johan Forsberg: Reproductive biology of some pierid butterflies. Hans Kautsky: Factors structuring phytobenthic communities in the Baltic Sea. Sven Boström: Morphological and systematic studies of the family Cephalobidae (Nematoda, Rhabditida). Lars G. Rudstam: Patterns of zooplanktivory in a coastal area of the northern Baltic proper. Sture Nellbring: Quantitative and qualitative studies of fish in shallow water, northern Baltic proper. Olof Leimar: Evolutionary analysis of animal fighting. Lena Svärd: Mating strategies of male butterflies in relation to female fecundity and polyandry.
Gunnar Fredriksson: Thyroid-like systems in endostyles: A study on morphology, function and evolution in "primitive" chordates. 1989. Magnus Rydevik: Smoltification and early sexual maturation in the Baltic salmon, Salmo salar L. Bengt Karlsson: Fecundity in butterflies: Adaptations and constraints. Rolf Gydemo: Studies on reproduction and growth in the noble crayfish, Astacus astacus L. Sture Hansson: Biotic interactions in fish and mysid communities, studies in two Baltic coastal areas. Brita Sundelin: Ecological effect assessment of pollutants using Baltic benthic organisms. Fredrik Pleijel: Taxonomy of the Phyllodocidae (Polychaeta). 1990. Lennart Edsman: Territoriality and competition in wall lizards. Dag Broman: Transport and fate of hydrophobic organic compounds in the Baltic aquatic environment - Polycyclic aromatic hydrocarbons, polychlorinated dibenzodioxins and dibenzofurans. Michael Tedengren: Ecophysiology and pollution sensitivity of Baltic Sea invertebrates. 1991. Sören Nylin: Butterfly life-history adaptations in seasonal environments. Mats Amundin: Sound production in Odontocetes with emphasis on the harbour porpoise, Phocoena phocoena. Kerstin Holmberg: Mallard ducks, mate choice and breeding success. Erland Dannelid: Dental morphology in eurasian shrews of the genus Sorex aspects on taxonomy, evolution and ecology. Catherine Hill: Mechanisms influencing the growth, reproduction and mortality of two co-occurring amphipod species in the Baltic sea. 1992. Sif Johansson: Regulating factors for coastal zooplankton community structure in the northern Baltic proper. Carl André: Settlement of bivalve larvae: the role of larval behaviour predation and hydrodynamics. Tomas Bollner: Regeneration and development of the nervous system in the ascidian Ciona intestinalis (L.). Eva Andersson: Neuroendocrine control of reproduction in the three-spined stickleback, Gasterosteus aculeatus (L.). Thorleifur Eiriksson: Female response and male singing strategies in two orthopteran species. 1993. Nina Wedell: Evolution of nuptial gifts in bushcrickets. Björn Forkman: The gathering and use of information in foraging.
C. Tomas Lundquist: Localization and chemical properties of peptides related to galanin and tachykinins in the blowfly nervous system. 1994. Tom Arnbom: Maternal investment in male and female offspring in the southern elephant seal. Anders Brodin: Time aspects on food hoarding in the willow tit - an evolutionary perspective. Gisela Holm: The tree-spined stickleback, Gasterosteus aculeatus L. in ecotoxicological test systems. Cecilia Lindblad: Perturbation of functions in shallow benthic ecosystems. 1995. Ulrik Kautsky: Ecosystem processes in coastal areas of the Baltic Sea. Kjell Wahlström: Natal dispersal in roe deer - an evolutionary perspective. Per Berggren: Stocks, status and survival of harbour porpoises in swedish waters. Anders Modig: Social behaviour and reproductive success in southern elephant seal (Mirounga leonina). 1996.
Michael Gilek: Bioaccumulation and cycling of hydrophobic organic contaminants by Baltic Sea blue mussels. Elin Sigvaldadottir: Systrematics of Spionidae and Prionospio (Polychaeta). Anders Silfvergrip: A systematic revision of the neotropical catfish genus Rhamdia (Teleostei, Pimelodidae). Agneta Johansson: Territorial dynamics and marking behaviour in male roe deer. Eric Muren: Tachykinin-related neuropeptides in the Madeira cockroach: structures distributions and actions.
1997. Niklas S. Mattson: Fish production and ecology in african small water bodies with emphasis on Tilapia. Thord Fransson: Time and energy in long distance bird migration. Birgitta Johansson: Oxygen deficiency and the ecology of Baltic macrobenthos. Johan Axelman: Biological, physico-chemical and biogeochemical dynamics of hydrophobic organic compounds. Marie Arnér: Organisms and food webs in rock pools: Responses to environmental stress and trophic manipulation. Pete Hurd: Game theoretical perspectives on conflict and biological communication. Erik Wilsson: Maternal effects on behaviour of juvenile and adult dogs. Magnus Tannerfeldt: Population fluctuations and life history consequences in the arctic fox.
Kristjan Lilliendahl: Fattening strategies in wintering passerines. Björn Birgersson: Maternal investment in male and female offspring in the fallow deer. Bohdan Sklepkovych: Kinship and conflict: resource competition in a protocooperative species: The Siberian Jay. 1998. Simon G.M. Ndaro: Ecological aspects of soft bottom meiofauna in Eastern Africa. Efthimia Antonopoulou: Feedback control of reproduction in Atlantic salmon, Salmo salar, male parr. Petra Wallberg: Distribution and fate of polychlorinated biphenyls within the pelagic microbial food web. Carl Rolff: Stable isotope studies of contaminant and material transport in Baltic pelagic food-webs. Marcus Öhman: Aspects of habitat and disturbance effects on tropical reeffish communities. Cecilia Kullberg: Behaviour under predation risk in birds. Thomas Lyrholm: Sperm whales: Social organization and global genetic structure. Min-Yung Kim: Neuropeptides related to tachykinins and leucokinins in the developing nervous system of insects. Salim M. Mohammed: Nutrient dynamics and exchanges between a mangrove forest and a coastal embayment: Chwaka Bay, Zanzibar. Gunilla Ejdung: Predatory processes in Baltic benthos. Virpi Sjöberg-Lindfors: Butterfly life history and mating systems. 1999. Karl Gotthard: Life history analysis of growth strategies in temperate butterflies. Niklas Janz: Ecology and evolution of butterfly host plant range. Staffan Jakobsson: Target organs for androgens in two teleost fishes, Atlantic salmon, Salmo salar, and three-spined stickleback, Gasterosteus aculeatus. Anna Thessing: Genetic and environmental factors influencing growth and survival in willow tits Parus montanus. Kenneth Ekvall: Alloparental care and social dynamics in the fallow deer (Dama dama). Gunilla Ericson: 32P-postlabelling analysis of DNA adducts in fish as a biomarker of genotoxic exposure. Karin Maria Björkman: Nutrient dynamics in the North Pacific subtropical gyre: Phosphorus fluxes in the upper oligotrophic ocean. 2000. Olle Israelsson: Xenoturbella.
Carl-Adam Wachtmeister: The evolution of courtship rituals. Cecilia Bornestaf: Mechanisms in the photoperiodic control of reproduction in the three-spined stickleback, Gasterosteus aculeatus. Olle Brick: Risk assessement and contest behaviour in the Cichlid fish, Nannacara anomala. Gabriella Gamberale-Stille: On the evolution and function of aposematic coloration. Helene Modig: Responses of Baltic soft-bottom invertebrates to settled organic material. 2001. Tomislav Vladic: Gonad and ejaculate allocation in alternative reproductive tactics of Salmon and Trout with reference to sperm competition. Susanne Stenius: Cooperation and conflict during reproduction in polyterritorial wood warblers (Phylloscopus sibilatrix). Ruben Tastàs-Duque: Studies of Cecidomyiidae (Diptera). Sven Burreau: On the uptake and biomagnification of PCBs and PBDEs in fish and aquatic food chains. Åsa Winther: Distribution and actions of insect tachykinin-related peptides. Fang Fang Kullander: Phylogeny and species diversity of the South and Southeast Asian cyprinid genus Danio Hamilton (Teleostei, Cyprinidae). Magnus G. S. Persson: Distribution and modulatory action of neuropeptides in the insect ventral nerve cord. Minna Miettinen: Egg carrying in the golden egg bug. Stefano Gihrlanda: Towards a theory of stimulus control. Annkristin H. Axén: Behaviour of Lycaenid butterfly larvae in their mutualistic interactions with ants. 2002. Patrik Lindenfors: Phylogenetic analyses of sexual size dimorphism. Patrik Börjesson: Geographical variation and resource use in harbour porpoises. Michael Norén: Phylogeny and classification of prolecithophoran flatworms. Johan Liljeblad: Phylogeny and evolution of gall wasps (Hymenoptera: Cynipidae) Ulf S. Johansson: Clades in the "higher land bird assemblage" 2003. Ulf Norberg: Evolution of dispersal and habitat exploration in butterflies. Johan Lind: Adaptive body regulation in the life history of birds. Olle Karlsson: Population structure, movements and site fidelity of grey seals in the Baltic Sea.
Helena A D Johard: Neuropeptide signaling in insects: peptide binding sites, tachykinin receptors and SNAP-25 Bodil Elmhagen: Interference competition between arctic and red foxes. Henrik Lange: Social dominance and agonistic communication in the great tit. Anna Hellqvist: The brain-pituitary-gonadal axis and gonadotropic hormones in the three-spined stickleback, Gasterosteus acculeatus. Anders Bignert: Biological aspects and statistical methods to improve assessments in environmental monitoring. Julia Carlström: Bycatch, conservation and echolocation of harbour porpoises. Kenth Svartberg: Personality in dogs. Susanna Hall: Moult strategies in relation to migration in long-distance migrants Miklós Páll: Role of 11-ketotestosterone and prolaction in the control of reproductive behaviour in the male three-spined stickleback, Gasterosteus aculeatus. Bo Delling: Species diversity and phylogeny of Salmo with emphasis on southern trouts (Teleostei, Salmonidae). Karolina Westlund: On post-confilict affiliation in humans and other primates - methodological considerations. Malin Ah-King: Phylogenetic analyses of parental care evolution. 2004. Jonas Bergström: The evolution of mating rates in Pieris napi Jörgen Ullberg: Dispersal in free-living, marine, benthic nematodes: passive or active processes? Eva Stensland: Behavioural ecology of Indo-Pacific bottlenose and humpback dolphins. Helena Strömberg: Benthic cryptofauna and internal bioeroders on coral reefs. Liselotte Jansson: Evolution of signal form. Martin Irestedt: Molecular systematics of the antbird-ovenbird comples. (Aves: Furnariida) Jesper Nyström: Predator - prey interactions of raptors in an arctic community. Ola Svensson: Sexual selection in Pomatoschistus - nests, sperm competition, and paternal care. 2005. Anders Bergström: Oviposition strategies in butterflies and consequences for conservation.
Helena Elofsson: Speerm motility in Gasterosteiform fishes. The role of salinity and ovarian fluid. Fredrik Stjernholm: Allocation of body resources to reproduction in butterflies. Fredrik Dalerum: Sociality in a solitary carnivore, the wolverine. Ana Beramendi: Morphological and functional studies on the Drosophila neuromuscular system during postembryonic stages. Georg H. Nygren: Latitudinal patterns in butterfly life history and host plant choice. Love Dalén: Distribution and abundance of genetic variation in the arctic fox. Ulrika Kaby: Attacking predators and fleeing prey: detection, escape and targeting behaviour in birds. 2006. Yasutaka Hamasaka: Multiple neurotransmitter inputs modulate circadian clock neurons in Drosophila. Rasmus Hovmöller: Molecular phylogenetics and taxonomic issues in dragonfly systematics (Insecta: Odonata) Adrian Vallin: On the protective value of conspicuous eyespots in Lepidoptera. Ryan Tyge Birse: Tachykinin-related peptide signaling and its role in metabolic stress in Drosophila. Lissåker Maria: Paternal care, filial cannibalism and sexual conflict in the sand goby, Pomatoschistus minutus. 2007. Ulrika Alm Bergvall: Food choice in fallow deer - experimental studies of selectivity. Petra Souter: Causes and consequences of spatial genetic variation in two species of scleractinian coral in East Africa. Hanne Løvlie: Pre- and post-copulatory sexual selection in the fowl, Gallus gallus. Kajsa Garpe: Effects of habitat structure on tropical fish assemblages. Erica Sjölin: Tubificids with trifid chaetae: morphology and phylogeny of Heterodrilus (Clitellata, Annelida) 2008. Enfjäll Karin: Mobility and emigration in butterflies. Berger David: Body size evolution in butterflies. Dehghani Reihaneh: Aspects of carnivoran evolution in Africa. Ohlson I. Jan: Molecular phylogeny of tyrant flycatchers, cotingas, manakins and their allies (Aves: Tyrannida) Weingartner Elisabeth: Phylogenetic perspective on host plant use, colonization and speciation in butterflies.
Mehnert Kerstin: Circadian plasticity in the neuromuscular junction of Drosophila melanogaster. Larsson Lena: disentangling small genetic differences in large Atlantic herring populations: comparing genetic markers and statistical poweer. 2009. Pena Carlos: Evolutionary history of the butterfly subfamily Satyrinae (Lepidoptera: Nymphalidae). Almbro Maria: Excape flight in butterflies. Hallgren Stefan: Aromatase in the guppy, Poecilia reticulata Distribution, control and role in behaviour. Mwandaya Augustine: Fish community patterns in Tanzanian mangrove creeks. Envall Ida: Evolutionary Perspectives on Naidinae (Annelida, Clitellata, Naididae): Molecular and Morphological Revelations. Henshaw Ian: Avian migration: the role of geomagnetic cues. Balogh Alexandra: Predator psychology and mimicry evolution - a theoretical analysis. Kodandaramaiah Ullasa: The dispersal-vicariance pendulum and butterfly biogeography. Dimitrova Marina: Life at stake when playing hide and seek. Friberg Magne: The evolutionary ecology of niche separation. Wilhelmsson Dan: Aspects of offshore renewable energy and the alterations of marine habitats. 2010. Amir Omar: Biology, ecology and anthropogenic threats of Indo-Pacific bottlenose dolphins in east Africa. Malm Tobias: Climbing the Trichoptera Tree - Investigations of Branches and Leaves. Nyström Veronica: Studies of declining populations - temporal genetic analyses of two arctic mammals. Espeland Marianne: Diversification on an ancient Darwinian island. Kahsai Tesfai Lily: Distribution and modulatory roles of neuropeptides and neurotransmitters in the Drosophila brain. Palmé Anna: Assessing and monitoring genetic patterns for conservation purposes with special emphasis on Scandinavia. Liao Te-Yu: A phylogenetic analysis of rasborin fishes (Teleostei, Cyprinidae). Norén Karin: Genetic structure in the North - population connectivity and social organization in the Arctic fox.
2011. Andersson Mathias: Offshore wind farms - ecological effects of noise and habitat alteration on fish. Bergman Martin: The evolution of territoriality in butterflies. Enell Lina: Chemical signalling in the Drosophila brain. Aronsson Hanna: On sexual imprinting in humans. Kolodziejczyk Agata: Chemical circuitry in the visual system of the fruitfly, Drosophila melanogaster. Särnblad Hansson Anna: Ecology and genetic population structure of IndoPacific bottlenose dolphins in East Africa. Yahya Saleh: Habitat structure, degradation and management effects on coral reef fish communities. Söderberg Jeannette: Neuropeptides and GABA in control of insulin producing cells in Drosophila. Johansen Aleksandra: Seasonal change in defensive coloration in a shieldbug. Charlier Johan: Monitoring gene level biodiversity - aspects and considerations in the context of conservation. Tobias Kånneby: Gastrotricha of Sweden - Biodiversity and Phylogeny. 2012. Lina Söderlind: Life history consequences of host plant choice in the comma butterfly. Magnus Gelang: Babblers, Biogeography and Bayesian Reasoning. Jessica Slove Davidson: The plasticity and geography of host use and the diversification of butterflies. Marianne Aronsson: Colour patterns in warning displays. Yi Ta Shao: The brain-pituitary-gonadal axis of the three-spined stickleback, Gasterosteus aculeatus. Neval Kapan: Regulation of insulin producing cells, stress responses and metabolism in Drosophila. Helena Larsdotter Mellström: Life history evolution in a bivoltine butterfly. 2013. Tomas Meijer: To survive and reproduce in a cyclic environment demography and conservation of the Arctic fox in Scandinavia. Martin Olofsson: Antipredator defence in butterflies. Julia Stigenberg: Hidden Creatures - systematics of the Euphorinae (Hymenoptera). Emma Lind: Genetic responce to pollution in sticklebacks; natural selection in the wild. Oskar Henriksson: Genetic connectivity of fish in the Western Indian Ocean.
George Sangster: Integravite taxonomy of birds: Studies into the nature, origin and delimitation of species. Jiangnan Luo: Regulation of insulin signaling and its developmental and functional roles on peptidergic neurons in the Drosophila central nervous system. 2014. Mija Jansson: Assessing inbreeding and loss of genetic variation in canids, domestic dog (Canis familiaris) and wolf (Canis lupus), using pedigree data. Marianne Pasanen Mortensen: Anthropogenic impact on predator guilds and ecosystem processes - Apex predator extinctions, land use and climate change. Peter Hellström: Predator responses to non-stationary rodent cycles. Inger Haugen: The diapause switch - Evolution of alternative developmental pathways in a butterfly. Inga Meyer-Wachsmuth: Through the magnifying glass - The big small world of marine meiofauna. Eleftheria Palkopoulou: Genetic structure, demographic change and extinction dynamics in the collared lemming and woolly mammoth. Jean-Luc Tison: Genetic variation and inference of demographic histories in non-model species. 2015. Karolina Tégélaar: Dynamics of the aphid-ant mutualism.